Exon 4-encoded acidic domain in the epithelium-restricted Ets factor, ESX, confers potent transactivating capacity and binds to TATA-binding protein (TBP)

Functional implications of paralog genes in polyglutamine spinocerebellar ataxias

Polyglutamine (polyQ) spinocerebellar ataxias (SCAs) comprise a group of autosomal dominant neurodegenerative disorders caused by (CAG/CAA)n expansions. The elongated stretches of adjacent glutamines alter the conformation of the native proteins inducing neurotoxicity, and subsequent motor and neurological symptoms. Although the etiology and neuropathology of most polyQ SCAs have been extensively studied, only a limited selection of therapies is available. Previous studies on SCA1 demonstrated that ATXN1L, a human duplicated gene of the disease-associated ATXN1, alleviated neuropathology in mice models. Other SCA-associated genes have paralogs (i.e., copies at different chromosomal locations derived from duplication of the parental gene), but their functional relevance and potential role in disease pathogenesis remain unexplored. Here, we review the protein homology, expression pattern, and molecular functions of paralogs in seven polyQ dominant ataxias-SCA1, SCA2, MJD/SCA3, SCA6, SCA7, SCA17, and DRPLA. Besides ATXN1L, we highlight ATXN2L, ATXN3L, CACNA1B, ATXN7L1, ATXN7L2, TBPL2, and RERE as promising functional candidates to play a role in the neuropathology of the respective SCA, along with the parental gene. Although most of these duplicates lack the (CAG/CAA)n region, if functionally redundant, they may compensate for a partial loss-of-function or dysfunction of the wild-type genes in SCAs. We aim to draw attention to the hypothesis that paralogs of disease-associated genes may underlie the complex neuropathology of dominant ataxias and potentiate new therapeutic strategies.

Nanopore Sequencing Unveils Diverse Transcript Variants of the Epithelial Cell-Specific Transcription Factor Elf-3 in Human Malignancies

The human E74-like ETS transcription factor 3 (Elf-3) is an epithelium-specific member of the ETS family, all members of which are characterized by a highly conserved DNA-binding domain. Elf-3 plays a crucial role in epithelial cell differentiation by participating in morphogenesis and terminal differentiation of the murine small intestinal epithelium, and also acts as an indispensable regulator of mesenchymal to epithelial transition, underlying its significant involvement in development and in pathological states, such as cancer. Although previous research works have deciphered the functional role of Elf-3 in normal physiology as well as in tumorigenesis, the present study highlights for the first time the wide spectrum of ELF3 mRNAs that are transcribed, providing an in-depth analysis of splicing events and exon/intron boundaries in a broad panel of human cell lines. The implementation of a versatile targeted nanopore sequencing approach led to the identification of 25 novel ELF3 mRNA transcript variants (ELF3 v.3–v.27) with new alternative splicing events, as well as two novel exons. Although the current study provides a qualitative transcriptional profile regarding ELF3, further studies must be conducted, so the biological function of all novel alternative transcript variants as well as the putative protein isoforms are elucidated.

ETS transcription factor ESE-1/Elf3 is an independent prognostic factor of survival in HR+HER2+ breast cancer patients

PURPOSE

The ETS transcription factor ESE-1 has been shown to be important in HER2⁺ breast cancer and ESE-1 mRNA expression has been shown to associate with prognostic outcomes in the HER2⁺ subtype, as well as in ER⁺, HER2⁺ luminal B patients. However, the clinical significance of ESE-1 protein expression remains unknown. The purpose of the current exploratory study is to evaluate the prognostic value of ESE-1 protein expression in molecular breast cancer subtypes with special emphasis on hormone receptor positive HER2⁺(HR⁺ HER2⁺) and the HER2 positive (HER2⁺-only) breast cancer patients.

METHODS

We developed a mouse monoclonal anti-ESE-1 antibody, verified its specificity, epitope, and used immunohistochemical staining to assess ESE-1 expression in an IBC approved archive of 957 breast tumor samples. Using Pearson product correlation, contingency analysis, and long rank P value testing, we analyzed the association of ESE-1 expression with clinicopathological features and survival outcomes in HR⁺HER2^-; HR⁺HER2⁺; HR^- HER2^- (Triple negative) and HR^-HER2⁺ (HER2 subtype) patients.

RESULTS

ESE-1, nuclear or cytoplasmic, was not significantly associated with survival outcomes in HR⁺HER2^-, triple-negative, or HER2⁺-only breast cancer patients. However, high nuclear ESE-1 was associated with poor survival outcomes in hormone receptor positive (ERα⁺, PR⁺) HER2⁺ patients and was an independent prognostic marker for that group.

CONCLUSIONS

This study provides evidence for prognostic significance of nuclear ESE-1 in ERalpha positive breast cancers patients also positive for HER2 indicating that crosstalk between ERalpha and ESE-1 in HER2⁺ tumors could be important for prognostic outcomes. Further studies regarding the nature of interaction between ESE-1 and ERalpha in these tumors are warranted.

Transcription Factor Elf3 Modulates Vasopressin-Induced Aquaporin-2 Gene Expression in Kidney Collecting Duct Cells

Aquaporin-2 (AQP2) is a molecular water channel protein responsible for water reabsorption by the kidney collecting ducts. Many water balance disorders are associated with defects in AQP2 gene expression regulated by the peptide hormone vasopressin. Here, we studied roles of Elf3 (E26 transformation-specific (Ets)-related transcription factor 3) in AQP2 gene expression in the collecting duct cells (mpkCCD). Vasopressin increased AQP2 mRNA and protein levels without affecting AQP2 mRNA degradation, indicative of transcriptional regulation. Elf3 knockdown and overexpression, respectively, reduced and increased AQP2 gene expression under basal and vasopressin-stimulated conditions. However, the vasopressin-to-basal ratios of AQP2 gene expression levels remained constant, indicating that Elf3 does not directly mediate vasopressin response but modulates the level of AQP2 gene expression inducible by vasopressin. The Elf3-modulated AQP2 gene expression was associated with AQP2 promoter activity, in line with Elf3’s ability to bind an Ets element in the AQP2 promoter. Mutation in the Ets element reduced both basal and vasopressin-stimulated AQP2 promoter activity, again without affecting vasopressin-to-basal ratios of the AQP2 promoter activity. Lithium chloride reduced both Elf3 and AQP2 mRNA in the mpkCCD cells as well as in mouse kidney inner medulla. We conclude that Elf3 modulates AQP2 promoter activity thereby gauging vasopressin-inducible AQP2 gene expression levels. Our data provide a potential explanation to lithium-induced nephrogenic diabetes insipidus where lithium reduces Elf3 and hence AQP2 abundance.

ELF3 is a repressor of androgen receptor action in prostate cancer cells

The androgen receptor (AR) has a critical role in the development and progression of prostate cancer (PC) and is a major therapeutic target in this disease. The transcriptional activity of AR is modulated by the coregulators with which it interacts, and consequently deregulation of cofactor expression and/or activity impacts the expression of genes whose products can have a role in PC pathogenesis. Here we report that E74-like factor 3 (ELF3), a member of the ETS family of transcription factors, is a repressor of AR transcriptional activity. Exogenous expression of ELF3 represses AR transcriptional activity when assessed using reporter-based transfection assays or when evaluated on endogenous AR target genes. Conversely, ELF3 knock down increases the AR transcriptional activity. Biochemical dissection of this activity indicates that it results from the physical interaction between ELF3 and AR and that this interaction inhibits the recruitment of AR to specific androgen response elements within target gene promoters. Significantly, we observed that depletion of ELF3 expression in LNCaP cells promotes cell migration, whereas increased ELF3 expression severely inhibits tumor growth in vitro and in a mouse xenograft model. Taken together, these results suggest that modulation of ELF3 expression and/or AR/ELF3 interaction may have utility in the treatment of PC.

[Biological functions of the duplicated GGAA-motifs in various human promoter regions]

Transcription is one of the most fundamental cellular functions and is an enzyme-complex mediated reaction that converts DNA sequences into mRNA. TATA-box is known to be an important motif for transcription. However, there are majority of promoters that have no TATA-box. They are called as TATA-less promoters and possess other elements that determine the transcription start site (TSS) of the genes. Multiple protein factors including ETS family proteins are known to recognize and bind to the GGAA containing sequences. In addition, it has been reported that the ETS binding motifs play important roles in regulation of various promoters. Here, we propose that the duplication and multiplication of the GGAA motifs are responsible for the initiation of transcription from TATA-less promoters.

Mapping of ESE-1 subdomains required to initiate mammary epithelial cell transformation via a cytoplasmic mechanism

BACKGROUND

The ETS family transcription factor ESE-1 is often overexpressed in human breast cancer. ESE-1 initiates transformation of MCF-12A cells via a non-transcriptional, cytoplasmic process that is mediated by a unique 40-amino acid serine and aspartic acid rich (SAR) subdomain, whereas, ESE-1's nuclear transcriptional property is required to maintain the transformed phenotype of MCF7, ZR-75-1 and T47D breast cancer cells.

RESULTS

To map the minimal functional nuclear localization (NLS) and nuclear export (NES) signals, we fused in-frame putative NLS and NES motifs between GFP and the SAR domain. Using these GFP constructs as reporters of subcellular localization, we mapped a single NLS to six basic amino acids (242 HGKRRR 247) in the AT-hook and two CRM1-dependent NES motifs, one to the pointed domain (NES1: 102 LCNCALEELRL 112) and another to the DNA binding domain (DBD), (NES2: 275 LWEFIRDILI 284). Moreover, analysis of a putative NLS located in the DBD (316 GQKKKNSN 323) by a similar GFP-SAR reporter or by internal deletion of the DBD, revealed this sequence to lack NLS activity. To assess the role of NES2 in regulating ESE-1 subcellular localization and subsequent transformation potency, we site-specifically mutagenized NES2, within full-length GFP-ESE-1 and GFP-NES2-SAR reporter constructs. These studies show that site-specific mutation of NES2 completely abrogates ESE-1 transforming activity. Furthermore, we show that exclusive cytoplasmic targeting of the SAR domain is sufficient to initiate transformation, and we report that an intact SAR domain is required, since block mutagenesis reveals that an intact SAR domain is necessary to maintain its full transforming potency. Finally, using a monoclonal antibody targeting the SAR domain, we demonstrate that the SAR domain contains a region accessible for protein - protein interactions.

CONCLUSIONS

These data highlight that ESE-1 contains NLS and NES signals that play a critical role in regulating its subcellular localization and function, and that an intact SAR domain mediates MEC transformation exclusively in the cytoplasm, via a novel nontranscriptional mechanism, whereby the SAR motif is accessible for ligand and/or protein interactions. These findings are significant, since they provide novel molecular insights into the functions of ETS transcription factors in mammary cell transformation.

The possible functions of duplicated ets (GGAA) motifs located near transcription start sites of various human genes

Transcription is one of the most fundamental nuclear functions and is an enzyme complex-mediated reaction that converts DNA sequences into mRNA. Analyzing DNA sequences of 5′-flanking regions of several human genes that respond to 12-O-tetradecanoyl-phorbol-13-acetate (TPA) in HL-60 cells, we have identified that the ets (GGAA) motifs are duplicated, overlapped, or clustered within a 500-bp distance from the most 5′-upstream region of the cDNA. Multiple protein factors including Ets family proteins are known to recognize and bind to the GGAA containing sequences. In addition, it has been reported that the ets motifs play important roles in regulation of various promoters. Here, we propose a molecular mechanism, defined by the presence of duplication and multiplication of the GGAA motifs, that is responsible for the initiation of transcription of several genes and for the recruitment of binding proteins to the transcription start site (TSS) of TATA-less promoters.

Transactivation of lung lysozyme expression by Ets family member ESE-1

Epithelial-specific Ets (ESE) transcription factors, consisting of ESE-1, ESE-2, and ESE-3, are constitutively expressed in distinct epithelia of mucosal tissues, including the lung. Each ESE member exhibits alternative splicing and yields at least two isoforms (a and b) with transcriptional targets largely unidentified. The studies described herein define a novel role for ESE transcription factors in transactivation of the human lysozyme gene ( LYZ), an essential component of innate defense in lung epithelia. Of the six ESE isoforms, ESE-1a and ESE-1b transactivated LYZ promoter in reporter gene assays, whereas only ESE-1b dramatically upregulated transcription of endogenous LYZ in both nonpulmonary and pulmonary epithelial cells. Importantly, ESE-1a and ESE-1b could transactivate the LYZ promoter in cultured primary airway epithelial cells. ESE-2 and ESE-3 isoforms were unable to substantially transactivate the lysozyme promoter or upregulate transcription of endogenous LYZ. Two functional consensus Ets sites located in the proximal 130-bp LYZ promoter were responsive to ESE-1b as identified by site-directed mutagenesis and DNA binding assays. Short hairpin RNA attenuation of endogenous ESE-1b mRNA levels in lung epithelia resulted in decreased LYZ transcription. Furthermore, ESE-1 antibody specifically enriched the 130-bp proximal LYZ promoter in chromatin immunoprecipitation analyses. These findings define a novel role for ESE transcription factors in regulating lung innate defense and suggest distinct regulatory functions for ESE family members.

Different domains of the transcription factor ELF3 are required in a promoter-specific manner and multiple domains control its binding to DNA

Elf3 is an epithelially restricted member of the ETS transcription factor family, which is involved in a wide range of normal cellular processes. Elf3 is also aberrantly expressed in several cancers, including breast cancer. To better understand the molecular mechanisms by which Elf3 regulates these processes, we created a large series of Elf3 mutant proteins with specific domains deleted or targeted by point mutations. The modified forms of Elf3 were used to analyze the contribution of each domain to DNA binding and the activation of gene expression. Our work demonstrates that three regions of Elf3, in addition to its DNA binding domain (ETS domain), influence Elf3 binding to DNA, including the transactivation domain that behaves as an autoinhibitory domain. Interestingly, disruption of the transactivation domain relieves the autoinhibition of Elf3 and enhances Elf3 binding to DNA. On the basis of these studies, we suggest a model for autoinhibition of Elf3 involving intramolecular interactions. Importantly, this model is consistent with our finding that the N-terminal region of Elf3, which contains the transactivation domain, interacts with its C terminus, which contains the ETS domain. In parallel studies, we demonstrate that residues flanking the N- and C-terminal sides of the ETS domain of Elf3 are crucial for its binding to DNA. Our studies also show that an AT-hook domain, as well as the serine- and aspartic acid-rich domain but not the pointed domain, is necessary for Elf3 activation of promoter activity. Unexpectedly, we determined that one of the AT-hook domains is required in a promoter-specific manner.

Determination of the consensus DNA-binding sequence and a transcriptional activation domain for ESE-2

The ESE (epithelium-specific Ets) subfamily of Ets transcription factors plays an important role in regulating gene expression in a variety of epithelial cell types. Although ESE proteins have been shown to bind to regulatory elements of some epithelial genes, the optimal DNA-binding sequence has not been experimentally ascertained for any member of the ESE subfamily of transcription factors. This has made the identification and validation of their targets difficult. We are studying ESE-2 (Elf5), which is highly expressed in epithelial cells of many tissues including skin keratinocytes. Here, we identify the preferred DNA-binding site of ESE-2 by performing CASTing (cyclic amplification and selection of targets) experiments. Our analysis shows that the optimal ESE-2 consensus motif consists of a GGA core and an AT-rich 5'- and 3'-flanking sequences. Mutational and competition experiments demonstrate that the flanking sequences that confer high DNA-binding affinity for ESE-2 show considerable differences from the known consensus DNA-binding sites of other Ets proteins, thus reinforcing the idea that the flanking sequences may impart recognition specificity for Ets proteins. In addition, we have identified a novel isoform of murine ESE-2, ESE-2L, that is generated by use of a hitherto unreported new exon and an alternate promoter. Interestingly, transient transfection assays with an optimal ESE-2 responsive reporter show that both ESE-2 and ESE-2L are weak transactivators. However, similar studies utilizing GAL4 chimaeras of ESE-2 demonstrate that while the DNA-binding ETS (E twenty-six) domain functions as a repressor, the PNT (pointed domain) of ESE-2 can act as a potent transcriptional activation domain. This novel transactivating property of PNT is also shared by ESE-3, another ESE family member. Identification of the ESE-2 consensus site and characterization of the transcriptional activation properties of ESE-2 shed new light on its potential as a regulator of target genes.

Identification of an epithelial-specific enhancer regulating ESX expression

The Ets transcription factor, ESX, exhibits a unique pattern of epithelial-restricted expression and transactivates genes involved in epithelial differentiation and cancer. The aim of this study was to determine the underlying genetic basis for epithelial-specific expression of ESX. We have identified a 30bp ESX enhancer sequence (EES) approximately 3 kb upstream of the proximal promoter. This region displays enhancer activity in an epithelial-specific manner and deletion of this region abrogates ESX gene transcription. An EES binding protein complex (EBC) was identified through electrophoretic mobility shift assays whose degree of EES binding correlated well with endogenous ESX levels in epithelial cells and was regulated by epithelial differentiation. Understanding the regulation of this element will lend insight into mechanisms of epithelial differentiation and the etiology of breast cancer and may provide novel targets for cancer therapeutic intervention.

The ETS transcription factor ESE-1 transforms MCF-12A human mammary epithelial cells via a novel cytoplasmic mechanism

Several different transcription factors, including estrogen receptor, progesterone receptor, and ETS family members, have been implicated in human breast cancer, indicating that transcription factor-induced alterations in gene expression underlie mammary cell transformation. ESE-1 is an epithelium-specific ETS transcription factor that contains two distinguishing domains, a serine- and aspartic acid-rich (SAR) domain and an AT hook domain. ESE-1 is abundantly expressed in human breast cancer and trans-activates epithelium-specific gene promoters in transient transfection assays. While it has been presumed that ETS factors transform mammary epithelial cells via their nuclear transcriptional functions, here we show (i) that ESE-1 protein is cytoplasmic in human breast cancer cells; (ii) that stably expressed green fluorescent protein-ESE-1 transforms MCF-12A human mammary epithelial cells; and (iii) that the ESE-1 SAR domain, acting in the cytoplasm, is necessary and sufficient to mediate this transformation. Deletion of transcriptional regulatory or nuclear localization domains does not impair ESE-1-mediated transformation, whereas fusing the simian virus 40 T-antigen nuclear localization signal to various ESE-1 constructs, including the SAR domain alone, inhibits their transforming capacity. Finally, we show that the nuclear localization of ESE-1 protein induces apoptosis in nontransformed mammary epithelial cells via a transcription-dependent mechanism. Together, our studies reveal two distinct ESE-1 functions, apoptosis and transformation, where the ESE-1 transcription activation domain contributes to apoptosis and the SAR domain mediates transformation via a novel nonnuclear, nontranscriptional mechanism. These studies not only describe a unique ETS factor transformation mechanism but also establish a new paradigm for cell transformation in general.

Partially unspliced and fully spliced ELF3 mRNA, including a new Alu element in human breast cancer

Using modified representational difference analysis, a DNA fragment (GC3) was isolated as a difference between a breast cancer and a normal cell line from the same patient. GC3 proved to be a fragment of intron 7 of the ELF3 gene, an ets family transcription factor, amplified in the breast cancer cell line. Using genomic walking technology, a new Alu (Alu(kwd)) was found downstream of GC3 in an antisense position between nt 8762 and nt 8763 within intron 8 of the ELF3 gene. This ELF3 intron fragment(GC3) was expressed in human breast cancer cell lines and four of six breast cancer tissues, but not in matched normal cell lines and tissues. Similarly, Alu(kwd) was also found in the same breast cancer cell lines and five of eight other breast cancer tissues, but not in matched normal cell lines and tissue. This was confirmed by RNase and DNase digestion analysis. Moreover, GC3 and Alu(kwd) were detected in both the nuclear and cytoplasmic RNA fractions of breast cancer cell lines. The finding of cytoplasmic intron retention was verified with northern blotting and the 5' and 3' rapid amplification cDNA ends procedure (5' and 3'RACE) to search for cDNA sequences in RNA from these cancer cell lines. Partially unspliced ELF3 mRNA and fully spliced ELF3 mRNA was found in the same breast cancer cell line. Partially unspliced ELF3 mRNA contained introns 4-7 without any nucleotide mutation at intron/exon splice junction borders. Fully spliced 1959 bp ELF3 mRNA showed a different 5'UTR from the published ELF3 mRNA, and was predicted to encode a 371 amino acid protein sharing 98% homology with the ELF3 protein sequence. This is the first report of intron retention of ELF3 as well as the pathological appearance of both spliced and unspliced cytoplasmic ELF3 mRNA in human breast cancer cells.

ESX induces transformation and functional epithelial to mesenchymal transition in MCF-12A mammary epithelial cells

ESX is an epithelial-restricted member of a large family of transcription factors known as the Ets family. ESX expression has been shown to be correlated with Her2/neu proto-oncogene amplification in highly aggressive breast cancers and induced by Her2/neu in breast cell lines, but its role in tumorigenesis is unknown. Previously, we have shown that ESX enhances breast cell survival in colony-formation assays. In order to determine whether ESX can act as a transforming gene, we stably transfected MCF-12A human mammary epithelial cells with the ESX expression vector, pCGN2-HA-ESX. The MCF-12A cell line is immortalized, but nontransformed, and importantly, these cells fail to express endogenous ESX protein. We used pCGN2-HA-Ets-2 and pSVRas expression vectors as positive controls for transformation. Like HA-Ets-2 and V12-Ras, stable expression of ESX induced EGF-independent proliferation, serum-independent MAPK phosphorylation and growth in soft agar. Additionally, stable ESX expression conferred increased cell adhesion, motility and invasion in two-dimensional and transwell filter assays, and an epithelial to mesenchymal morphological transition. In three-dimensional cultures, parental and vector control (pCGN2) cells formed highly organized duct-like structures with evidence of cell polarity, ECM adhesion-dependent proliferation and cell survival, and lack of cellular invasion into surrounding matrix. Remarkably, the ESX stable cells formed solid, disorganized structures, with lack of cell polarity, loss of adhesion junctions and cytokeratin staining and loss of dependence on ECM adhesion for cell proliferation and survival. In addition, ESX cells invaded the surrounding matrix, indicative of a transformed and metastatic phenotype. Taken together, these data show that ESX expression alone confers a transformed and in vitro metastatic phenotype to otherwise normal MCF-12A cells.

The epithelial-specific ETS transcription factor ESX/ESE-1/Elf-3 modulates breast cancer-associated gene expression

Several members of the ETS family of transcription factors contribute to tumorigenesis in many different tissues, including breast epithelium. The ESX gene is an epithelial-specific Ets member that is particularly relevant to breast cancer. ESX is amplified in early breast cancers, it is overexpressed in human breast ductal carcinoma in situ, and there may be a positive feedback loop between the HER2/neu proto-oncogene and ESX. Despite this progress in our understanding of ESX, its ability to regulate tumor-related gene expression and to modulate breast cell survival, remain unknown. Here we show that HA-ESX stimulates the collagenase and HER2/neu promoters, but fails to activate an intact stromelysin promoter. However, HA-ESX activates, in a dose-dependent manner, a heterologous promoter containing eight copies of the Ets binding site derived from the stromelysin gene (p8Xpal-CAT). Analysis of the ability of constructs encoding nine Ets family members to activate the HER2/neu promoter revealed three patterns of gene activation: (1) no effect or repressed promoter activity (Elk-1 and NET); (2) intermediate activity (ER81, GABP, ESX, and HA-Ets-2); and, (3) maximal activity (Ets-1, VP-16-Ets-1, and EHF). Based on these observations, we also determined whether ESX is capable of conferring a survival phenotype upon immortalized, but nontransformed and ESX negative MCF-12A human breast cells. Using a colony formation assay, we found that HA-ESX and HA-Ets-2, mediated MCF-12A cell survival rates that approached those generated by oncogenic V12 Ras, whereas empty vector resulted in negligible colony formation. By contrast, in immortalized and transformed T47D breast cancer cells, which express both HER2/neu and ESX, we found that antisense and dominant-negative HA-ESX inhibited T47D colony formation, whereas control vector allowed formation of many colonies. These results are significant because they show that HA-ESX is able to differentially activate several malignancy-associated gene promoters, and that ESX expression is required for cellular survival of nontransformed MCF-12A and transformed T47D human mammary cells.

External control of Her2 expression and cancer cell growth by targeting a Ras-linked coactivator

Overproduction of the Her2 oncoprotein has been found in approximately 30% of breast tumors, and patients who have Her2 excesses typically have more aggressive disease. Here we show that the expression of the Her2 gene can be decreased by inhibiting the interaction of the two cancer-linked proteins, DRIP130/CRSP130/Sur-2 (a Ras-linked subunit of human mediator complexes) and ESX (an epithelial-restricted transcription factor). Disruption of the interaction by a short cell-permeable peptide reduced the expression of the Her2 gene and specifically impaired the growth and viability of Her2-overexpressing breast cancer cells. The association of ESX with DRIP130 is mediated by a small hydrophobic face of an 8-aa helix in ESX, suggesting a therapeutic approach to incapacitating the Her2 gene by small organic molecules.

ErbB2 activation of ESX gene expression

Various members of the Ets multigene family exhibit diverse roles in development, cell differentiation, tissue-specific gene expression and human malignancy. In the search for Ets factors involved in mammary gland development and malignancy, ESX was found to be upregulated in a subset of breast tumours and cell lines. We report the transcriptional regulation of ESX in epithelial breast cancer cells. Transient reporter assays using the ESX promoter show that ESX transcription is regulated by ErbB receptor signalling. In cell lines and in 45 primary ductal breast cancers we show that ESX transcript expression significantly correlates with ErbB2 transcript levels. Moreover, expression of ErbB2 in cells upregulates ESX promoter activity while inhibition of ErbB2 or its downstream signaling pathways decrease both ESX promoter activity and endogenous ESX protein levels. These results indicate that the ESX promoter represents a transcriptional target of ErbB2, and ESX expression may represent a downstream mediator of ErbB2 signaling and ErbB2-induced gene expression.

Activation of the murine type II transforming growth factor-beta receptor gene: up-regulation and function of the transcription factor Elf-3/Ert/Esx/Ese-1

Previous studies demonstrated that differentiation of mouse embryonal carcinoma cells leads to transcriptional up-regulation of the mouse type II transforming growth factor-beta receptor (mTbetaR-II) gene. To elucidate the molecular mechanisms regulating transcription of this gene, we isolated the 5'-flanking region of the mTbetaR-II gene and characterized its expression in F9-differentiated cells. Analysis of mTbetaR-II promoter/reporter gene constructs demonstrates that two conserved Ets-binding sites play an important role in the activity of the mTbetaR-II promoter. Importantly, we present evidence that mElf-3, a member of the Ets family, plays a key role in the activation of the mTbetaR-II promoter. Northern blot analysis reveals that the steady-state levels of mTbetaR-II mRNA increase in parallel with those of mElf-3 mRNA during the differentiation of F9 embryonal carcinoma cells. We also demonstrate that mElf-3 contains one or more domains that influence its binding to DNA. Finally, we report that a single amino acid substitution in the transactivation domain of mElf-3 reduces its ability to transactivate and elevates its steady-state levels of expression. In conclusion, our data argue that mElf-3 plays a key role in the regulation of the mTbetaR-II gene, and Elf-3 itself is regulated at multiple levels.

Ets regulation of the erbB2 promoter

Evaluating the chromatinized erbB2 gene in nuclei from breast cancer cells expressing varying levels of ErbB2 transcripts, we identified a nuclease-sensitive site within a 0.22 kb region of maximum enhancer activity centered over a conserved 28 bp polypurine(GGA)-polypyrimidine(TCC) mirror-repeat and an adjacent essential Ets binding site (EBS). Promoter footprinting with nuclear extracts reveals an intense Ets hypersensitivity site at the EBS whose degree of intensity correlates with the level of cellular ErbB2 expression. In vitro mapping assays show that the supercoiled erbB2 promoter forms an internal triplex structure (Hr-DNA) at the mirror-repeat element. Mutations preventing Hr-DNA formation can enhance erbB2 promoter activity in human breast cancer cells, a result consistent with previous demonstration that Ets-erbB2 promoter complexes cannot form when the mirror-repeat is engaged in triplex binding, and new results suggesting that Ets binding induces severe promoter bending that may restrict local triplex formation. In addition to previously described erbB2-regulating breast cancer Ets factors (PEA3, ESX/Elf-3), Elf-1 is now shown to be another endogenously expressed Ets candidate capable of binding to and upregulating the erbB2 promoter. Given current strategies to transcriptionally inhibit ErbB2 overexpression, including development of novel erbB2 promoter-targeted therapeutics, an EBS-targeted approach is presented using chimeric Ets proteins that strongly repress erbB2 promoter activity.

Targeting the ets binding site of the HER2/neu promoter with pyrrole-imidazole polyamides

Three DNA binding polyamides () were synthesized that bind with high affinity (K(a) = 8.7. 10(9) m(-1) to 1.4. 10(10) m(-1)) to two 7-base pair sequences overlapping the Ets DNA binding site (EBS; GAGGAA) within the regulatory region of the HER2/neu proximal promoter. As measured by electrophoretic mobility shift assay, polyamides binding to flanking elements upstream () or downstream (2 and 3) of the EBS were one to two orders of magnitude more effective than the natural product distamycin at inhibiting formation of complexes between the purified EBS protein, epithelial restricted with serine box (ESX), and the HER2/neu promoter probe. One polyamide, 2, completely blocked Ets-DNA complex formation at 10 nm ligand concentration, whereas formation of activator protein-2-DNA complexes was unaffected at the activator protein-2 binding site immediately upstream of the HER2/neu EBS, even at 100 nm ligand concentration. At equilibrium, polyamide 1 was equally effective at inhibiting Ets/DNA binding when added before or after in vitro formation of protein-promoter complexes, demonstrating its utility to disrupt endogenous Ets-mediated HER2/neu preinitiation complexes. Polyamide 2, the most potent inhibitor of Ets-DNA complex formation by electrophoretic mobility shift assay, was also the most effective inhibitor of HER2/neu promoter-driven transcription measured in a cell-free system using nuclear extract from an ESX- and HER2/neu-overexpressing human breast cancer cell line, SKBR-3.

Dual function of the epithelial specific ets transcription factor, ELF3, in modulating differentiation

The ets family of transcription factors comprises many members which contribute to diverse cellular functions that vary depending upon the cell- and tissue-type context. Recently, different groups have identified a novel member of the ets family that is epithelial-specific. Variably called ESE-1, ERT, jen, ESX, this gene is designated currently as ELF3. In order to understand transcriptional regulatory mechanisms mediated by ELF3, we investigated its effect on the human keratin 4 gene promoter based upon the role of keratin 4 in early differentiation of the esophageal squamous epithelium. Interestingly, ELF3 suppressed basal keratin 4 promoter activity in both esophageal and cervical epithelial cancer cell lines, a novel result, while simultaneously activating the late-differentiation linked SPRR2A promoter. Furthermore, serial deletion constructs of the keratin 4 promoter continued to be suppressed by ELF3, a phenomenon that was only partially rescued by ELF3 ets domain mutants, but completely abrogated by deletion of the ELF3 pointed domain. These results suggest that ELF3 may have dual functions in the transcriptional regulation of genes involved in squamous epithelial differentiation. One of these functions may not be exclusively mediated through DNA binding in the context of transcriptional suppression of the keratin 4 promoter.